A liquid cooling system can be installed to an information technology (IT) rack. The liquid cooling system can include a cooling assembly that has a cooling chassis and cold plates fixed at a bottom portion of the cooling chassis. Fluid lines are arranged in an interior of the cooling chassis to fluidly connect the cold plates to a supply line and a return line. The cooling chassis includes an outlet port that provides a path for a leaked fluid to flow out of the cooling chassis. The outlet port is inserted into an opening of a detection channel that has one or more fluid sensors within the detection channel. The floor of the cooling chassis may have a shape or other features to assist flow of leaked fluid towards the outlet port to assist in depositing the leaked fluid in the detection channel.

A server tray assembly includes a server tray support configured to receive a server board that includes a working fluid conduit fluidly coupled to a server board connector disposed on a back plane of the server board, a back wall of the server tray support includes a fluid connector configured to form an unbiased fluid connection with the server board connector; and a locking assembly secured to at least one of a server rack or the server tray support, the locking assembly disposed opposite the fluid connector is configured to engage a portion of the server board to bias the server board toward the fluid connector to fluidly seal the unbiased fluid connection between the server board connector and the fluid connector of the server tray support.

A flow path module, adapted to a heat exchange element and a coolant and including a pipeline structure and at least one flow resistance element, is provided. The pipeline structure is adapted to be connected to the heat exchange element. The flow resistance element is disposed in the pipeline structure, and the coolant flows through the heat exchange element from the pipeline structure. A flow resistance of the flow resistance element is adapted to be adjusted corresponding to a flow resistance of the heat exchange element. A coolant distribution device and a server are also provided.

Connectors for a networking device may be provided. A networking device may comprise a first plurality of switch bars each comprising a first switch type arranged parallel to one another, a second plurality of switch bars each comprising a second switch type arranged parallel to one another, and a third plurality of switch bars each comprising a third switch type arranged parallel to one another. The first plurality of switch bars, the second plurality of switch bars, and the third plurality of switch bars may be arranged orthogonally. A first one of the first plurality of switch bars may be connected to a first one of the second plurality of switch bars via a retractable mechanical connector mechanism.

A liquid cooled server chassis comprising a chassis, at least one electronics module having at least one heat generating component mounted thereon, and a liquid cooling unit, having at least one liquid plate heat exchanger, a liquid row heat sink, an inlet chassis manifold, and an outlet chassis manifold, is provided. The at least one liquid plate heat exchanger, mounted and thermally coupled to the at least one heat generating component, is in fluid communication with the inlet chassis manifold and outlet chassis manifold, transporting heat away from the at least one heat generating component. The liquid row heat sink, in fluid communication with the inlet chassis manifold and outlet chassis manifold, is configured to lower a flowthrough temperature of ambient airflow flowing through the liquid row heat sink. The at least one electronics module and liquid row heat sink are parallel arranged, whereby cooling power is evenly distributed thereamong.

An immersion cooling system includes a first casing, a plurality of fins, a liquid-cooled pipeline, and a liquid-cooled system. The first casing is used for containing a dielectric liquid in which a heat-generating component is immersed. The plurality of fins are disposed on and located outside the first casing. The liquid-cooled pipeline containing a coolant is attached to the first casing. The liquid-cooled system is disposed outside the first casing and connected with the liquid-cooled pipeline to remove heat from the coolant in the liquid-cooled pipeline. The immersion cooling system dissipates heat through two heat exchange mechanisms, that is, natural convection heat loss and heat absorption by liquid cooling.

A cooling system can distribute fluid to and from IT equipment in an IT rack which can be understood as a server rack which houses multiple servers. The cooling system can include three distribution channels for the server rack. At least one of the distribution channels can be connected to valves that are arranged to operate that distribution channel in a bi-directional manner. This bi-directional distribution channel can switch operation if any of the other distribution channels becomes inoperative.

A liquid-submersible thermal management system includes a cylindrical outer shell and an inner shell positioned in an interior volume of the outer shell. The cylindrical outer shell has a longitudinal axis oriented vertically relative to a direction of gravity, and the inner shell defines an immersion chamber. The liquid-submersible thermal management system a spine positioned inside the immersion chamber and oriented at least partially in a direction of the longitudinal axis with a heat-generating component located in the immersion chamber. A working fluid is positioned in the immersion chamber and at least partially surrounding the heat-generating component. The working fluid receives heat from the heat-generating component.

A self-contained mobile high performance computing platform for cryptocurrency mining is disclosed. The self-contained mobile high performance computing platform includes a mobile cabinet, which includes wheels for easy movement and placement within, for example, a warehouse facility, a garage, a basement, an office tower, or a vehicle such as a truck or van. The cabinet is configured to enclose at least one computing apparatus, which includes computing blades immersed in an oil or other dielectric fluid for immersion cooling. The computing blades are configured to be connected to respective interface boards via connectors that are located within a tank of the dielectric fluid. Each computing blade may be individually removed or replaced, thereby enabling an inoperable or low performance computing blade to be disconnected without affecting the operations of the other computing blades.

An electronic equipment chassis comprises a chassis housing and two or more cooling compartments in the chassis housing. At least a first one of the two or more cooling compartments in the chassis housing utilizes a first type of cooling for a first set of electronic equipment housed therein, and at least a second one of the two or more cooling compartments in the chassis housing utilizes a second type of cooling for a second set of electronic equipment housed therein. The first type of cooling comprises liquid immersion cooling and the second type of cooling comprises non-liquid immersion cooling.